Posts
A cure for spinal cord injury?
Diabetes? Macular degeneration? Hope or just
hype?
There are now some clinical trials
using embryonic stem cells to treat
serious diseases for which no other good therapy is currently available. But
this is just the beginning of a major medical megatrend that will blossom forth
in the coming years.
Embryonic stem
cells are present after a fertilized egg divides for two or three days. They
have the seemingly miraculous ability to turn into any of the tissue types in
the body—whether brain neurons, beating heart cells, bone, or pancreatic islet
cells. It is important to understand just where these cells come from. Those
used in science are the byproduct of in vitro fertilization (IVF), cells taken
from the often “left over” embryos that are otherwise discarded.
In 1998,
scientists under the leadership of Dr James Thomson at the University of
Wisconsin, learned how to take some of the cells from these about to be
discarded embryos and put them into a cell culture – basically a fluid in which
the cells can grow to produce more cells. These cells in turn can then be
directed to grow into heart or lung or pancreas or other types of cells by the
addition of various additives to the fluid in which they are growing. So it is
from these discards that embryonic stem cells are available to us. Just to be
clear. The blastocyst or embryo with its 32 or so cells is not grown in the
culture dish. Rather, individual cells are removed and allowed to divide and
grow. These are the so called embryonic stem cells. But no embryo is growing,
just individual cells.
It is true that
much can be done with adult stem cells as discussed last time but science so
far suggests that embryonic stem cells hold promise for much more benefit. It
will probably be embryonic stem cells (or perhaps induced pluipotent stem cells
– see the first in this series) that pave the way for replacing the islet cells
of the pancreas with new insulin producing cells to cure diabetes or replace
the damaged cells in the brain that are key to Parkinson’s disease. Some
strongly feel that it is wrong to use cells from embryos. It is important to
remember that these are fertilized eggs that were prepared for couples that
could not conceive and so had eggs and sperm placed into a dish with special
fluids. Experience has shown that success is better if the doctor implants a
few embryos into the woman’s uterus rather than just one. But the doctor may
have more than enough embryos and the extras will be discarded if the woman
becomes pregnant. I look at it this way. Since the embryos will be destroyed
anyway, why not use them for creating stem cells that perhaps many people with
diverse diseases might benefit from. It is not dissimilar to transplanting the
organs of a person who has died in a car accident rather than burying them in
the grave. And the embryo, made up of just a few cells, is disrupted so each
cell grows independently. Now the cells can be stimulated to become heart
cells, liver cells or whatever and might be useful in treating a disease. It
will take some years but there will certainly be major advances down the road in
how we can repair, restore or replace damaged tissues or organs.
The pace at which
we benefit from stem cell therapy will be influenced by factors including
cultural attitudes which in turn lead to legislative decisions and legal
challanges. The issues revolving around federal funding via the NIH for
research on embryonic stem cells reached the federal courts two summers ago and
were further addressed by an appellate court in April of 2011. Cohen and
Adashi, writing in the New England Journal of
Medicine in May, 2011, gave a clear account of the debate in the courts.
They concluded with “It is difficult to
overestimate the vast potential of stem-cell research. We believe we cannot
afford to allow ongoing legal ambiguities to compromise this line of scientific
pursuit. Quite the contrary, now is the time to pick up the pace with an eye
toward realizing the hoped-for translational benefits. With statutory relief
deemed unlikely to be provided before the 2012 elections, it appears all but
inevitable that the matter of funding of human ESC research will have to be
settled in a court of law.” Of course that never happened and stem cell
research is not high on the public’s set of concerns for this year’s elections
but the makeup of the coming Congress after the election could be relevant down
the road.
Here is an example
of how stem cells could be used: islet cells on demand– One day, and I believe
it will occur within five to ten years, stem cells will be able to be mass
grown into islet cells. They will be ready when the patient needs them. Just
give them by vein and they will home into where they need to go. And if they are created from the process
called nuclear transfer or adult cells reprogrammed from the patient by genes
(iPSC) or proteins (piPSC) that I described previously, they probably will not
be rejected because they will be developed to not provoke the immune system.
But still, whatever process destroyed their own islet cells years before will
probably still be functional. So these new cells may be destroyed over time as
well, unless some new technology or drugs are developed to prevent this cell
destruction by the body. But in the meantime, just come back for a new infusion
whenever needed. Sort of like going to the gas station to refill the tank!
Islet cells
injected into the vein seem to know to go to the liver and live there and do
their work. Bone marrow stem cells when injected by vein go to the bone marrow,
take up residence and repopulate the marrow of the patient with leukemia who
just got very aggressive treatments to eliminate all of his own marrow cells
(and hopefully all of the leukemia cells as well.) But would all stem cells
know where to go? Or what to do? Would they go to the heart after a heart
attack or do they need to be infused directly into the coronary arteries or
injected into the heart muscle itself? And stem cells or stem cells prompted to
develop into brain cells – will they need to be injected directly into those
areas of the brain damaged by Parkinson’s or Alzheimer’s diseases? These are
but a few of the issues to be resolved with careful research.
Here are just a
few studies in progress, some in animals, some in humans and many in laboratory
settings:
iPS
cells have been created for multiple different diseases by taking cells from
affected patients such as diabetes type
I, Lou Gehrig’s disease (amyotrophic lateral sclerosis), Gaucher’s disease and muscular dystrophy. It is hoped that
these cells will help explain the disease processes and their origination. In
addition, they might prove useful in growing large numbers of mature cells that
could in turn be used for drug screening and drug toxicity evaluations. And in
this regard, iPSCs and piPSCs matured into cardiac cells are already being used
by pharmaceutical companies to test new drugs for side effects.
We all know that
if we have a tooth pulled, that’s it – a tooth won’t grow back. But an
intriguing study has taken the cells of the progenitors of the molars from
mouse embryos and grown them in culture for a few days. Meanwhile, a molar or
two from multiple adult mice were extracted. Then the stem cells were implanted
into that space and within two months the mice had new teeth with normal
structure and strength, demonstrating that stem cells in the proper setting can
lead to the re-growth of an organ or tissue. Think about the potential in
humans to get a real new tooth rather than a prosthetic tooth or a bridge when
a diseased or damaged tooth must be extracted.
One of the most
exciting studies to get underway was a phase 1 trial of stem cells in patients
with spinal cord damage. The Geron Company
began this FDA-approved trial in late 2010. They took human embryonic stem
cells and from them derived oligodendrocyte progenitor
cells; in other words, nerve cells. These were injected next to the spinal cord
at the level of very recent injury. In extensive animal experiments, these
cells were found able to cause the damaged spinal cord cells to remylinate
(basically reapply an “insulator” as with the covering of an electric wire) and
to create some type of nerve growth stimulation with remarkable restoration of
some or all function. The rats began to move much more normally within just a
week or so of the injection. Then came the human trial. It was Phase 1 meaning
that it was all about studying if the injected cells would cause any toxicity.
It is a good guess that they would not but because they were be used initially
in low dosage (relative to what was used in the rats to obtain responses) so it
is unlikely any functional improvement would occur. That would be the test in
later trials (Phase 2 and 3) with higher cell numbers provided this Phase 1
study proceeded successfully. As it turned out, Geron Corporation ended the
study after enrolling just four patients citing lack of adequate funding to
continue. This left Advanced Cell Technology, Inc. as the only other American
company conducting a study of embryonic stem cells – for macular degeneration
and for macular dystrophy in the eyes. They use embryonic stem cells to produce
retinal epithelial pigment cells to be injected behind the retina in affected
patients. Results will be forthcoming.
Another very early Phase I study, this one using adult stem
cells, is just beginning in Israel for amyotrophic lateral sclerosis (ALS). The
patient’s own bone marrow stem cells will be treated in the laboratory with a
proprietary process by BrainStorm
Cell Therapeutics and then placed back into patients. So far 12 of 24
patients have been treated with no apparent adverse effects. The final results
will be of real interest.
As I said at the beginning, there is still much to be learned
before stem cells will become routinely utilized for patient care – but
progress is real and the opportunities are exciting for a major transformation
of medical care in the coming years. It is becoming more hope than hype. Here, as with genomics, we see the value
and the importance of innovation. Scientists with good ideas taking the steps
needed to bring new and until recently almost undreamed of possibilities to transform
healthcare – clearly a medical megatrend in the making.
